HydRand:高效的连续分布随机性

Philipp Schindler, Aljosha Judmayer, Nicholas Stifter, E. Weippl
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引用次数: 42

摘要

可靠的随机性来源不仅是各种加密、安全和分布式系统协议的基本构建块,而且在许多新的区块链建议的设计中也起着不可或缺的作用。因此,可公开验证、抗偏见和不可预测的随机性的话题最近受到了越来越多的关注。特别是针对持续操作的随机信标协议,可以成为当前基于权益证明的分布式账本提案的重要组成部分。我们使用HydRand改进了以前的随机信标方法,HydRand是一种基于可公开验证的秘密共享(PVSS)的新型分布式协议,可确保随机信标值连续序列的不可预测性、抗偏倚性和可公开验证性。此外,在存在对抗行为的情况下,HydRand以定期和可预测的间隔提供保证的随机性输出,并且不依赖于可信任的经销商进行初始设置。与现有的基于PVSS的努力实现类似属性的方法相比,我们的解决方案通过将通信复杂度从$\mathcal{O}\left({{n^3}} \right)$降低到$\mathcal{O}\left({{n^2}} \right)$来提高可扩展性。此外,我们是第一个详细比较最近描述的可用于实现随机信标的方案和协议的人。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
HydRand: Efficient Continuous Distributed Randomness
A reliable source of randomness is not only an essential building block in various cryptographic, security, and distributed systems protocols, but also plays an integral part in the design of many new blockchain proposals. Consequently, the topic of publicly-verifiable, bias-resistant and unpredictable randomness has recently enjoyed increased attention. In particular random beacon protocols, aimed at continuous operation, can be a vital component for current Proof-of-Stake based distributed ledger proposals. We improve upon previous random beacon approaches with HydRand, a novel distributed protocol based on publicly-verifiable secret sharing (PVSS) to ensure unpredictability, bias-resistance, and public-verifiability of a continuous sequence of random beacon values. Furthermore, HydRand provides guaranteed output delivery of randomness at regular and predictable intervals in the presence of adversarial behavior and does not rely on a trusted dealer for the initial setup. Compared to existing PVSS based approaches that strive to achieve similar properties, our solution improves scalability by lowering the communication complexity from $\mathcal{O}\left( {{n^3}} \right)$ to $\mathcal{O}\left( {{n^2}} \right)$ . Furthermore, we are the first to present a detailed comparison of recently described schemes and protocols that can be used for implementing random beacons.
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